Fast interpolation and time-optimization with contact

dc.contributor.author

Hauser, K

dc.date.accessioned

2015-07-15T13:09:40Z

dc.date.accessioned

2015-07-15T13:12:08Z

dc.date.issued

2014-01-01

dc.description.abstract

© The Author(s) 2014.This paper presents a method for generating dynamically feasible, keyframe-interpolating motions for robots undergoing contact, such as in legged locomotion and manipulation. The first stage generates a twice-differentiable interpolating path that obeys kinematic contact constraints up to a user-specified tolerance. The second stage optimizes speeds along the path to minimize time while satisfying dynamic constraints. The method supports velocity, acceleration, and torque constraints, and polyhedral contact friction constraints at an arbitrary number of contact points. The method is numerically stable, and empirical running time is weakly linear in the number of degrees of freedom and polynomial in the time-domain grid resolution. Experiments demonstrate that full-body motions for robots with 100 degrees of freedom and dozens of contact points are calculated in seconds.

dc.identifier.eissn

1741-3176

dc.identifier.issn

0278-3649

dc.identifier.uri

https://hdl.handle.net/10161/10306

dc.publisher

SAGE Publications

dc.relation.ispartof

International Journal of Robotics Research

dc.relation.isversionof

10.1177/0278364914527855

dc.relation.replaces

http://hdl.handle.net/10161/10305

dc.relation.replaces

10161/10305

dc.title

Fast interpolation and time-optimization with contact

dc.type

Journal article

pubs.begin-page

1231

pubs.end-page

1250

pubs.issue

9

pubs.organisational-group

Computer Science

pubs.organisational-group

Duke

pubs.organisational-group

Electrical and Computer Engineering

pubs.organisational-group

Pratt School of Engineering

pubs.organisational-group

Trinity College of Arts & Sciences

pubs.publication-status

Published

pubs.volume

33

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